Expert-level photonics covering guided wave optics, laser physics, nonlinear optics, optical communications, integrated photonics, and quantum photonics.
Total internal reflection: light confined in high-index waveguide core. Single mode fiber: one transverse mode, no modal dispersion, long-haul communications. Multimode fiber: multiple modes, modal dispersion limits bandwidth-distance product. Dispersion: chromatic dispersion broadens pulses, limits data rate. Fiber attenuation: lowest at 1550nm, about 0.2 dB per km in silica fiber.
Population inversion: more atoms in excited than ground state, required for gain. Gain medium: semiconductor, gas, solid-state crystal, fiber. Resonator: mirrors form cavity, select longitudinal modes. Threshold: gain must exceed cavity losses for lasing. Mode-locking: ultrashort pulses from coherent superposition of longitudinal modes.
Second harmonic generation: two photons combine to produce one at double frequency. Parametric amplification: signal amplified by pump via chi-2 interaction. Four-wave mixing: three waves interact via chi-3 to generate fourth. Kerr effect: intensity-dependent refractive index causes self-phase modulation. Solitons: pulse shape preserved by balance of dispersion and nonlinearity.
Silicon photonics: CMOS-compatible, low cost, high volume manufacture. Ring resonators: compact wavelength filters, modulators, sensors. Mach-Zehnder: interferometric modulator, electro-optic or thermo-optic tuning. Photonic integrated circuits: waveguides, splitters, modulators, detectors on chip.
| Pitfall | Fix |
|---|---|
| Ignoring fiber polarization | Use polarization-maintaining fiber for sensitive applications |
| Underestimating coupling losses | Measure insertion loss carefully at each interface |
| Nonlinear effects at high power | Calculate nonlinear length and compare to system length |
| Etalon effects from reflections | Use angled facets and index matching fluid |